A comparative study of plasma membrane Mg2+-ATPase activities in normal,regenerating and malignant cells

Plasma membranes have been prepared from rat normal liver cells, regenerating liver cells and Yoshida ascites hepatoma 66 cells after intact cells were first bound to polylysine-coated polyacrylamide beads, and the membrane-associated Mg²⁺-ATPase activity was assayed directly on beads with membrane attached. With plasma membranes from normal liver cells, K_m for ATP and V were found to be higher than those in regenerating liver cells and hepatoma cells. Vanadate caused a different sensitivity of the activity, without an effect in normal liver cells and with an inhibition in regenerating liver cells and hepatoma cells. The activity in normal and regenerating liver cells decreased with increasing temperature above 24–30°C, while the activity in hepatoma cells continued to increase linearly to 37°C. Unlike the enzyme in normal and regenerating liver cells, the hepatoma enzyme was shown to have a higher phase transition temperature and lower activation energies. In all three kinds of cells the activity was increased by the dephosphorylation of plasma membranes and unaffected by the phosphorylation. By means of histochemical Mg²⁺-ATPase staining applied on polyacrylamide gels, at least three major bands which show the enzymic activity were visible in normal and regenerating liver and a single band was detected in hepatoma cells.     

A study of the cell surface of tumour, foetal and lymph-node cells by cell electrophoresis after antibody and enzymic treatment

1. Rabbit anti-(rat foetal liver) serum, absorbed with adult rat liver cells, decreased the electrophoretic mobility of foetal liver cells by 51% and rat hepatoma cells by 45%, indicating the presence of a foetal-type antigen on the hepatoma cell membrane. 2. The chemical nature of the surface antigen was investigated. Incubation with neuraminidase had no effect on adult liver cells but decreased the electrophoretic mobility of foetal liver cells by 51% and of hepatoma cells by 34%; the effect of antiserum was decreased to one-fifth. 3. Sialic acid, or the supernatant from neuraminidase-treated cells, partially blocked the decrease in electrophoretic mobility induced by antiserum. 4. The pH-electrophoretic mobility curves of hepatoma cells treated with antisera were consistent with a sialic acidcontaining antigen on the surface of the tumour cells. 5. Treatment with ribonuclease did not decrease the electrophoretic mobility of adult-liver cells, but decreased that of the foetal liver cells by 17% and hepatoma cells by 29%. 6. In parallel studies made with mouse BP8 ascites-tumour cells ribonuclease decreased the electrophoretic mobility by 39%, that of normal mouse lymph-node cells by 4.8% and allergized mouse lymph-node cells by 13.3%. 7. Trypsin treatment also decreased the electrophoretic mobility of hepatoma cells by 22%.     

Gangliosides of hepatoma 27, normal and regenerating rat liver.

The highly malignant rat hepatoma 27 was found to have increased amounts of lipid-bound sialic acid as compared with normal liver whereas in regenerating liver the lipid-bound sialic acid level was reduced. In contrast to the liver the hepatoma contained higher amounts of disialogangliosides and no trisialogangliosides, which are abundant in the liver. The main disialoganglioside of the hepatoma had no analogue among the liver gangliosides and was identified as Gal-GalNAc(AcNeu-AcNeu)-Glc-Cer (GD1b), which in other tissues is known to be a precursor of trisialogangliosides. These findings may be explained by a reduced activity of glycosyltransferases in the hepatoma and apparently do not simply reflect differences in growth rate since the ganglioside pattern of regenerating rat liver was not altered significantly in comparison with the liver. Liver and hepatoma microsomes were found to be enriched in gangliosides as compared with whole cells, liver mitochondria were slightly poorer, while the ganglioside level of hepatoma mitochondria was much higher than that of the hepatoma cells. It thus appears that the existing image of the plasma membranes as the only sites of high ganglioside concentration may not hold true for weakly differentiated hepatomas of high malignancy.     

Changes in surface glycopeptides after malignant transformation of rat liver cells and during the regression of hepatoma cells

Normal liver cells, Zajdela's hepatoma cells, and regressing hepatoma cells were metabolically labeled with either radioactive glucosamine or mannose. Glycopeptides obtained by exhaustive pronase digestion of these cells were compared after fractionation by gel filtration on Bio-Gel P-6. Chemical analysis, affinity chromatography on immobilized lectins, alkaline treatment, and susceptibility toward endo-beta-N-acetylglucosaminidase and tunicamycin revealed dramatic changes in the glycopeptide patterns of transformed cells during the recovery of normal phenotype. The most prominent feature was the presence on the surface of hepatoma cells of a large glycopeptide, which was absent from normal liver cells and disappeared almost completely during the regression of hepatoma cells. This large glycopeptide had a Mr of 70,000, contained essentially O-glycosidically linked glycan chains, and did not result from a hypersialylation. N-glycosidically linked glycopeptides, high-mannose, and complex-type oligosaccharides were present in distinct proportions according to the differentiation state. Transformation of liver cells led to a reduction of high-mannose type oligosaccharides and an increase in the degree of branching of complex-type oligosaccharides. In addition, "bisected" glycopeptides were present only on hepatoma cells. The pattern of N-linked glycopeptides of normal liver cells was recovered during the regression of hepatoma cells. The origin of glycopeptide differences between normal and transformed cells and the evidence of a relation between carbohydrate changes, in particular the appearance of a large glycopeptide, and tumorigenicity are discussed.     

Gangliosides of plasma membranes from normal rat liver and Morris hepatoma.

Plasma membranes were isolated from normal rat liver and Morris hepatoma 5123tc by discontinuous sucrose gradient centrifugation. There was an average two and one-halffold enrichment of gangliosides in plasma membranes from normal liver and hepatoma as compared with their respective whole cells. The amount of total gangliosides in plasma membranes from hepatoma was eight times greater than that found in normal liver. This increase resulted from a fivefold increase in hematosides, an eightfold increase in monosialogangliosides and a twenty-twofold increase in disialogangliosides. Trisialogangliosides were present in normal liver but not in hepatoma.     

Elevated cholesterol and decreased sterol carrier protein-2 in peroxisomes from AS-30D hepatoma compared to normal rat liver

Peroxisomes were isolated from AS-30D hepatoma and compared to normal rat liver cells for the purpose of investigating the cholesterol accumulation in the hepatoma cells. Cholesterol was found to be approximately 10-fold higher relative to protein in AS-30D peroxisomes as compared to peroxisomes from normal liver. The peroxisomes from the hepatoma cells were found to be more stable; catalase was not released from these peroxisomes during isolation or osmotic shock of the peroxisomal fraction. The elevated cholesterol level may stabilize the peroxisomal membrane. Sterol carrier protein-2 (SCP-2) levels were measured using a radioimmunoassay (RIA), which indicated the highest concentration of SCP-2 to be in peroxisomes. Hepatoma peroxisomes had a lower concentration of SCP-2 (2.5 micrograms/mg) than normal liver peroxisomes (8 micrograms/mg). Approximately half of all SCP-2 detected was found to be soluble in both hepatoma and normal rat liver cells. Immunoblots from both rat liver and AS-30D fractions demonstrated the presence of the 14-kDa form of SCP-2. The liver fractions also had a 57-kDa immunoreactive protein, which was barely detectable in the AS-30D fractions. The low abundance of the high molecular weight form of SCP-2 from hepatoma peroxisomes and the lower amounts of SCP-2 detected in the AS-30D peroxisomes may be related to the accumulation of cholesterol in the cells.     

A simple procedure for the purification of calmodulin bound to membranes; calmodulin bound to the particulate fraction of AH-66 hepatoma ascites cells

We have demonstrated the identity of calmodulin tightly bound to the particulate fractions of AH-66 hepatoma cells and normal liver with authentic soluble calmodulin and have compared the particulate calmodulin content of AH-66 cells with that of normal liver. Calmodulin bound to the particulate fractions of the hepatoma and normal liver cells was purified to electrophoretic homogeneity by a simple procedure which involves solubilization of the particulate fractions with LIS, extraction of the solubilized solution with 37.5% phenol, gel filtration, and affinity chromatography on Fluphenazine-Sepharose. There were no detectable differences between the particulate calmodulin thus purified and authentic soluble calmodulin of rat brain. The particulate calmodulin in the hepatoma and normal liver cells was assayed based on its ability to activate calmodulin-deficient phosphodiesterase after partial purification of calmodulin from the particulate fractions by solubilization with LIS and extraction with phenol as described above. In addition, the particulate calmodulin content in the hepatoma and normal liver cells was also measured after solubilization of the particulate fractions with Lubrol PX. The results obtained by these two different procedures indicate that calmodulin content in the particulate fraction as well as in the soluble fraction of the hepatoma is significantly higher than that in the corresponding fractions of normal liver.     

Identification of albumin-synthesizing polysomes from mouse liver and a mouse hepatoma cell line.

Albumin-synthesizing polysomes from mouse liver and mouse hepatoma cells in in tissue culture have been localized on sucrose gradients with ¹²⁵I-labeled antimouse serum albumin used as a marker. Competition studies show that the ¹²⁵I-labeled antibody binds specifically to albumin-synthesizing polysomes from both tissues. The ¹²⁵I-labeled polysomes from liver and hepatoma cells have identical sedimentation properties on sucrose gradients, which indicates that the polysomes range in size from 9–14 ribosomes. This is comparable in size to polysomes from rat liver and Morris hepatoma. One significant difference between these albumin-synthesizing polysomes is that those extracted from hepatoma cells bind 70% less antibody than equivalent amounts of polysomes from liver cells. Since the level of albumin synthesis in the hepatoma cells is comparable to the level of albumin synthesis $\text{in vivo}$, this difference in antibody-binding capacity is not likely to be due to differences in polysomal content, but appears to be a characteristic difference between hepatoma and normal mouse liver cells.     

A novel human hepatoma cell line, FLC-4, exhibits highly enhanced liver differentiation functions through the three-dimensional cell shape

We characterized three-dimensional human hepatoma cell lines, functional liver cell (FLC) cell lines, to establish a highly differentiated hepatoma cell line. We investigated the effect of extracellular matrix and cell morphology on liver-specific gene expression in FLC cells. The hepatocyte nuclear factor-4α (HNF-4α) and other liver-specific gene expressions were enhanced in spherical FLC-4 cells on EHS-gel, but other human hepatoma cells such as HepG2 did not show the enhancement. Importantly, the liver-specific gene expression levels in spherical FLC-4 cells cultured on EHS-gel were comparable to those of human liver and were much higher than those of other human hepatoma cell lines. The major matrix components and growth factors in EHS-gel did not affect cell shape and liver functions. To exclude any effect of the extracellular matrix, we made spherical FLC-4 cells by actin filament disruption. The actin-disrupted spherical cells also showed an enhanced liver-specific gene expression. We concluded that three-dimensional cell shape per se is one of the most important determinants of liver differentiation functions in FLC-4 cells. Cell morphology-dependent induction of liver-specific gene expression was mediated through microtubule organization. In conclusion, differentiation of FLC-4 human hepatoma cell line can be enhanced to a human liver-like level through the three-dimensional cell shape in a microtubule-dependent manner.     

Structure and properties of an under-sulfated heparan sulfate proteoglycan synthesized by a rat hepatoma cell line

A rat hepatoma cell line was shown to synthesize heparan sulfate and chondroitin sulfate proteoglycans. Unlike cultured hepatocytes, the hepatoma cells did not deposit these proteoglycans into an extracellular matrix, and most of the newly synthesized heparan sulfate proteoglycans were secreted into the culture medium. Heparan sulfate proteoglycans were also found associated with the cell surface. These proteoglycans could be solubilized by mild trypsin or detergent treatment of the cells but could not be displaced from the cells by incubation with heparin. The detergent-solubilized heparan sulfate proteoglycan had a hydrophobic segment that enabled it to bind to octyl- Sepharose. This segment could conceivably anchor the molecule in the lipid interior of the plasma membrane. The size of the hepatoma heparan sulfate proteoglycans was similar to that of proteoglycans isolated from rat liver microsomes or from primary cultures of rat hepatocytes. Ion-exchange chromatography on DEAE-Sephacel indicated that the hepatoma heparan sulfate proteoglycans had a lower average charge density than the rat liver heparan sulfate proteoglycans. The lower charge density of the hepatoma heparan sulfate can be largely attributed to a reduced number of N-sulfated glucosamine units in the polysaccharide chain compared with that of rat liver heparan sulfate. Hepatoma heparan sulfate proteoglycans purified from the culture medium had a considerably lower affinity for fibronectin-Sepharose compared with that of rat liver heparan sulfate proteoglycans. Furthermore, the hepatoma proteoglycan did not bind to the neoplastic cells, whereas heparan sulfate from normal rat liver bound to the hepatoma cells in a time-dependent reaction. The possible consequences of the reduced sulfation of the heparan sulfate proteoglycan produced by the hepatoma cells are discussed in terms of the postulated roles of heparan sulfate in the regulation of cell growth and extracellular matrix formation.     

Sialyl transferase activities of rat ascites hepatoma cells and rat liver

Sialyl transferase activities of the homogenate of rat ascites hepatome cells were compared with normal rat liver homogenate. The former had only 20% of the activity of the latter when an exogenous acceptor was added in the reaction mixture.Toward endogenous receptors, the activity of the hepatoma cell homogenate was 50% of that of the normal cell homogenate. A stimulation of the activity toward endogenous acceptors was observed when the homogenate of rat ascites hepatoma cells and that of rat liver were mixed. This stimulatory effect seems to be the consequence of utilization of acceptors from ascites hepatoma cells by the sialyl transferases of the rat liver.     

Studies on DNA content of hepatocytes in cirrhosis and hepatoma by means of microspectrophotometry and radioautography

In order to clarify the underlying mechanism of malignant transformation from cirrhosis to hepatoma the cell kinetics of hepatocytes were studied in these two conditions. The content and synthesis of DNA in hepatocyte nuclei were investigated, by means of Feulgen-microspectrophotometry and tritiated thymidine radioautography, in cirrhotic and noncancerous parts of hepatoma with concomitant cirrhosis. The distribution of ploidy patterns was widely spread, from hypodiploid to hyperpolyploid, in the noncancerous parts of a cirrhotic liver containing hepatoma. In normal liver, each paired nuclear DNA content of a binucleate cell recorded almost the same amount, whereas in the noncancerous as well as in hepatoma cells much difference of DNA content was observed between the paired nuclei of the binucleate cells. The ploidy pattern of hepatocytes in patients with liver cirrhosis, who had developed hepatoma during follow-up periods of several months to several years, appeared to resemble that in noncancerous parts of hepatoma cases. On the other hand, the incorporation of tritiated thymidine into hepatocytes was found to be markedly increased in noncancerous parts as well as in cirrhotic liver developing hepatoma during follow-up periods. These results suggest the possibility that the hepatocytes in noncancerous parts of hepatoma have deranged cell-kinetics which might be a driving factor for the development of malignancy.     

Studies on DNA content of hepatocytes in cirrhosis and hepatoma by means of microspectrophotometry and radioautography

Summary In order to clarify the underlying mechanism of malignant transformation from cirrhosis to hepatoma the cell kinetics of hepatocytes were studied in these two conditions. The content and synthesis of DNA in hepatocyte nuclei were investigated, by means of Feulgen-microspectrophotometry and tritiated thymidine radioautography, in cirrhotic and noncancerous parts of hepatoma with concomitant cirrhosis. The distribution of ploidy patterns was widely spread, from hypodiploid to hyperpolyploid, in the noncancerous parts of a cirrhotic liver containing hepatoma. In normal liver, each paired nuclear DNA content of a binucleate cell recorded almost the same amount, whereas in the noncancerous as well as in hepatoma cells much difference of DNA content was observed between the paired nuclei of the binucleate cells. The ploidy pattern of hepatocytes in patients with liver cirrhosis, who had developed hepatoma during follow-up periods of several months to several years, appeared to resemble that in noncancerous parts of hepatoma cases. On the other hand, the incorporation of tritiated thymidine into hepatocytes was found to be markedly increased in noncancerous parts as well as in cirrhotic liver developing hepatoma during follow-up periods. These results suggest the possibility that the hepatocytes in noncancerous parts of hepatoma have deranged cell-kinetics which might be a driving factor for the development of malignancy.     

岩藻糖糖链与肝癌细胞的迁移作用

通过凝集素印迹转移电泳和亲和层析技术,对岩藻糖糖基化蛋白在肝癌细胞中的作用进行了研究.在化学诱发的大鼠肝癌过程中, 分子质量在23 ku到40 ku范围内与荆豆凝集素(UEA)及扁豆凝集素(LCA)结合的岩藻糖糖基化蛋白显著减少, 诱癌至17～20周这些条带重新恢复,而分子质量为80 ku的条带却在诱癌过程中逐周增加.比较高、低转移性肝癌细胞的岩藻糖糖基化蛋白, 发现高转移性肝癌细胞具有多种增强的条带.利用橘果粉胞凝集素(AAL)和LCA亲和层析柱分离了这些岩藻糖基化糖蛋白, 并用这些糖蛋白直接作用于肝癌细胞,发现AAL-糖蛋白具有显著抑制肝癌细胞迁移的作用,迁移细胞数从对照的(100±4.9)%下降到(48.1±2.5)% (P＜0.01), LCA-糖蛋白也有类似作用.用胰酶和木瓜蛋白酶水解蛋白质部分后,形成的糖肽抑制肝癌细胞迁移的作用并不改变,甚至增强.此外直接用肝癌转移灶的组织测定了岩藻糖转移酶活性,发现α1,6岩藻糖基转移酶活性显著比正常肝组织高,而α1,3岩藻糖基转移酶活性没有显著的改变.用系列凝集素分析发现这些糖链主要能结合伴刀豆凝集素A, 也能结合E-型及L-型植物凝集素, 显示这种糖蛋白的糖链可能含有较多的高甘露糖型.这些结果提示糖链在诱癌过程中结构有了改变,使之在肝癌细胞的迁移和转移中起重要作用.     

大鼠7SRNA顺序的分子克隆,其基因结构和细胞内分布的分析

The cDNA copy of in vitro polyadenylated 7s RNA from rat liver cells have been cloned and sequenced. One clone (p 24) contains a 7 s cDNA fragment with 180 bp from 3'end. Sequence analysis indicated that 7s RNA in rat liver cells showed at least one nucleotide substitution compared with that in rat Novikoff hepatoma cells. Southern blot of rat liver and hepatoma genomic DNA shows that 7s RNA gene is a multigene family (10-20 copies per haploid genome) and these loci seems not to be clustered, but have a dispersed array in the genome. We have determined the subcellular distribution of 7 s RNA in rat liver cell by means of RNA-excess hybridization. The result indicated that 42% 7s RNA exists in cell nuclei. Dot hybridization to RNA from liver cells and hepatoma cells proved that the normal liver cells contain relatively more 7 s RNA than that in hepatoma cells.     

Two-dimensional polyacrylamide gel electrophoresis of chromatin proteins of normal rat liver and Novikoff hepatoma ascites cells

Chromatin was prepared from the citric acid nuclei of normal rat liver and Novikoff hepatoma ascites cells. After sulfuric acid extraction, the dehistonized chromatin was solubilized by digestion with deoxyribonuclease I. The proteins of normal liver and of Novikoff hepatoma chromatin fractions were analyzed by two-dimensional polyacrylamide gel electrophoresis. The liver pattern contained 69 components and the hepatoma pattern contained 84 components. Comparison of the two patterns revealed two dense protein spots migrating in the B region in the liver pattern that were absent from the tumor pattern and two dense protein spots migrating in the C region in the tumor pattern that were absent from the liver pattern.     

In vitro differential effects of sodium selenite on the growth of human hepatoma cells and human embryonic liver cells

The effects of various concentrations of Na₂SeO₃ on human hepatoma cells and human embryonic liver cells was investigated in vitro. For human hepatoma cells, mitotic index and cell count decreased with increasing selenium concentrations. At 1 μg/mL Na₂SeO₃, mitotic activity of human hepatoma cells were partially arrested. In human embryonic liver cells continuously treated with Na₂SeO₃, (1 μg/mL) cell count of the treated group decreased only by d 7; mitotic index, labeled index, and mean silver grain number per 50 labeled nuclei were the same as in the control group on exposure to 1, 3, and 5 μg/mL for up to 72 h. In mixed cultures of human hepatoma and embryonic liver cells treated with 3 and 5 μg/mL of Na₂SeO₃ for 24 h, hepatoma cells showed vacuolated cytoplasms, distorted nuclei, condensed chromatin, and even pyknosis, whereas the embryonic liver cells retained a normal morphology under the same treatment.     

Production of an auto-stimulatory growth factor by human hepatoma cells abrogates requirement for a brain-derived factor

Summary Human hepatoma cells grow at high cell density in the absence of exogenous growth factors. At low cell density, two different hepatoma cell lines required a novel growth factor from brain tissue. A factor with similar physico-chemical properties in the concentrated medium from high density cultures completely substituted for the brain extract. The autogenous secretion of a novel liver cell growth factor that is concentrated in brain tissue may underlie in part the unregulated growth of hepatomas. EDITOR'S STATEMENT Collective properties of growth factor activities for hepatoma cells in bovine brain extract and the medium of hepatoma cells suggest a neural tissue-derived liver cell growth factor that may be autogenously produced by liver tumor cells. Purification and characterization of such a factor may lead to selective inhibition of hepatoma, cell proliferation. David W. Barnes